Sporozoites of mammalian malaria: attachment to, interiorization and fate within macrophages

Sporozoites of Plasmodium berghei and Plasmodium knowlesi, incubated in normal serum readily interact with peritoneal macrophages of mice or rhesus monkeys, respectively. Interiorization of the sporozoite requires that both serum and macrophages be obtained from an animal susceptible to infection by the malaria parasite. Serum requirements for sporozoite attachment to the macrophage are less specific. Phagocytosis is not essential for the parasites to become intracellular. Our findings indicate that active penetration of the sporozites into the macrohages does occur. Antibodies present in the serum of sporozoite-immunized mice are important in determining the fate of both the intracellular sporozoites and the macrophages containing the parasite. Sporozoites coated with antibodies degenerate within vacuoles of the macrophages, which have no morphologic alteration. Sporozoites incubated in normal serum do not degenerate within macrophages, but the parasitized macrophages become morphologically altered and are destroyed. Preliminary experiments indicate that sporozoites appear to interact with rat Kupffer cells in the same way as with the peritoneal mouse macrophages. It is postulated that Kupffer cells play a dual role in sporozoite-host cell interaction. In normal animals these cells might serve to localize the sporozoites in the immediate vicinity of the hepatocytes. In the immunized animals, macrophages would remove and destroy the antibody-coated parasites, thus contributing to sporozoite-induced resistance.     

Effects of Cationized Ferritin and Neuraminidase on Invasion of Cultured Cells by Eimeria meleagrimitis Sporozoites

Primary turkey kidney cells and Eimeria meleagrimitis sporozoites were treated with cationized ferritin (CF) or neuraminidase (NANase), and the effects on the invasion of the cells by the sporozoites were measured. Cultures of host cells pretreated with either compound contained significantly fewer intracellular sporozoites than did control cultures. There was little additive effect if cultures were first treated with NANase and then with CF. In contrast, pretreatment of sporozoites with CF or low concentrations of NANase had no effect on invasion. The inhibition of invasion was apparently due to an interaction between treatment substances and host cell surface rather than to direct effect on the sporozoites. The CF bound to the randomly distributed anionic sites on the surfaces of both host cells and sporozoites and then rapidly aggregated. Sporozoites, probably in the process of invading cells, were invariably found with the conoid in close association with aggregates of CF on the host cell membrane. The CF on the sporozoites was apparently shed before or during invasion because all intracellular sporozoites were completely devoid of the label.     

Sporozoites of Mammalian Malaria: Attachment To, Interiorization and Fate Within Macrophages

Sporozoites of Plasmodium berghei and Plasmodium knowlesi, incubated in normal serum readily interact with peritoneal macrophages of mice or rhesus monkeys, respectively. Interiorization of the sporozoite requires that both serum and macrophages be obtained from an animal susceptible to infection by the malaria parasite. Serum requirements for sporozoite attachment to the macrophage are less specific. Phagocytosis is not essential for the parasites to become intracellular. Our findings indicate that active penetration of the sporozoites into the macrophages does occur.     

Effects of cationized ferritin and neuraminidase on invasion of cultured cells by Eimeria meleagrimitis sporozoites

Primary turkey kidney cells and Eimeria meleagrimitis sporozoites were treated with cationized ferritin (CF) or neuraminidase ( NANase ), and the effects on the invasion of the cells by the sporozoites were measured. Cultures of host cells pretreated with either compound contained significantly fewer intracellular sporozoites than did control cultures. There was little additive effect if cultures were first treated with NANase and then with CF. In contrast, pretreatment of sporozoites with CF or low concentrations of NANase had no effect on invasion. The inhibition of invasion was apparently due to an interaction between treatment substances and host cell surface rather than to direct effect on the sporozoites. The CF bound to the randomly distributed anionic sites on the surfaces of both host cells and sporozoites and then rapidly aggregated. Sporozoites, probably in the process of invading cells, were invariably found with the conoid in close association with aggregates of CF on the host cell membrane. The CF on the sporozoites was apparently shed before or during invasion because all intracellular sporozoites were completely devoid of the label.     

Development of resistance to coccidiosis in the absence of merogonic development using X-irradiated Eimeria acervulina oocysts

Sporulated oocysts of the protozoan Eimeria acervulina were subjected to 0, 10, 15, 20, or 30 krad of X-irradiation and inoculated into susceptible outbred chickens to determine if radioattenuated coccidia could induce protection against parasite challenge. Irradiation treatment had an appreciable dose-dependent effect on parasite development. Insignificant numbers of oocysts were produced by chickens inoculated with parasites that had been exposed to greater than 10 krad X-irradiation. Sporozoites exposed to 15 or 20 krad irradiation conferred significant protection against the appearance of intestinal lesions after parasite challenge. Sporozoites subjected to the highest dose level (30 krad) did not produce any significant level of protection. To investigate this phenomenon further and assess intracellular parasite development, susceptible outbred strains of chickens were administered either nonirradiated (0 krad) oocysts or oocysts that were exposed to an optimal dose (15 krad) or a high dose (30 krad) of X-irradiation. Immunofluorescence staining of tissue sections from each treatment group at various intervals after the initial administration of irradiated parasites indicated that sporozoites exposed to 15 krad irradiation were as capable of invading the host intestinal epithelium as nonirradiated sporozoites. However, at 48, 60, 72, and 96 hr, there was a marked reduction in merogonic development in groups receiving irradiated sporozoites compared to those inoculated with nonirradiated parasites. The latter parasites underwent profuse merogonic development; in contrast, irradiated parasites demonstrated little (15 krad) or no (30 krad) merogonic development. These results suggest that induction of a protective immune response occurs during a critical period early in intracellular development of E. acervulina.     

Effects of Intestinal Contents from Normal and Immunized Mice on Sporozoites of Eimeria falciformis1

The interaction of Eimeria falciformis sporozoites with the intestinal epithelium and with the intestinal contents from the cecum and colon of normal and specifically immunized mice was studied by light (LM) and scanning electron (SEM) microscopy. Fecal (FM) and enterocyte-associated (EAM) mucus were removed from the cecum and colon of normal mice and mice that had been immunized 1, 6, 12, or 20 days earlier with a series of oral inoculations of E. falciformis oocysts. Sporozoite-specific IgA, but neither IgM nor IgG, was detected by the immunofluorescent antibody test in FM and EAM from immunized mice. No sporozoite-specific immunoglobulin was detected in normal mice. When examined by LM, sporozoites exposed to all FM and EAM preparations exhibited greater motility and excystation from sporocysts. At 4 h after incubation in FM or EAM from normal or immune mice, about 10% of the sporozoites appeared damaged, being non-motile and non-refractile. Immune FM and EAM caused agglutination of sporozoites and sporocysts and oocyst walls of E. falciformis. but did not agglutinate those of E. ferrisi. Scanning electron microscopy of in vitro interactions between E. falciformis sporozoites and intestinal contents revealed that sporozoites exposed to immune EAM were coated with particulate material whereas those exposed to normal EAM were relatively clean. Sporozoites exposed to immune FM were usually embedded within the mucus whereas those exposed to normal FM were situated on top of the mucus. No significant differences occurred between the length/width (L/W) ratios of sporozoites incubated in normal FM and EAM or in PBS. Sporozoites exposed to immune FM had significantly greater L/W ratios than those exposed to normal FM whereas those exposed to immune EAM had significantly shorter L/W ratios than ones exposed to normal EAM. Few of the sporozoites observed on the luminal surface of the colon and cecum of normal mice were covered by mucus and none was altered in shape or showed pellicular damage. Only a few sporozoites were observed on the luminal surface of the colon and cecum of immunized mice. Most of these were covered by mucus and some exhibited pellicular alterations.     

Cryopreservation of Leucocytozoon caulleryi Sporozoites

Leucocytozoon caulleryi sporozoites that had been stored at - 196° C or -80° C for 6 or 12 months in Eagle's minimum essential medium or Medium 199 supplemented with 5% glycerol and 10% chicken serum showed infectivity to chickens. Glycerol at a concentration of 10% and dimethyl sulfoxide at 10% and 5% were found to be ineffective cryoprotective agents for the low temperature preservation of sporozoites. Sporozoites isolated from the intact females of Culicoides arakawae , which had been stored at -80° C for 6 or 12 months without cryoprotective agents, retained their infectivity. No differences were observed in the prepatent period, duration of parasitemia, and presence of serum-soluble antigens between chickens infected with frozen sporozoites and those infected with fresh sporozoites.     

Eimeria maxima (Apicomplexa): a comparison of sporozoite transport in naive and immune chickens

This study compared the early stages of infection in naive and immune chickens infected with Eimeria maxima. An immunoperoxidase stain was developed and used to detect sporozoites and early schizonts in tissue sections of intestinal epithelium. A significantly higher proportion of sporozoites was present in the crypts of naive chickens, 48 hr postinoculation of oocysts, compared to immune chickens. Sporozoites in immune birds tended to remain in the lamina propria rather than migrate to the crypts. Sporozoites were found within intraepithelial lymphocytes (IEL's) in the epithelium, the lamina propria, and the crypts of both naive and immune chickens. Parasites in IEL's of immune birds at the ultrastructural level and there were no apparent morphological abnormalities. Livers and spleens, of both immune and naive chickens that had been inoculated with Eimeria maxima, produced patent infections when fed to susceptible chickens. Infections could be transferred up to 72 hr post-inoculation of the donor birds. Peak oocyst production in the recipient birds occurred 7-8 days after the transfers. This time period approximates the prepatent period in a natural infection and thus implies that the extraintestinal stage was a sporozoite.     

The viability and survival of sporozoites of Eimeria in vitro

Some factors affecting excystation and viability of sporozoites of several species of Eimeria from chickens were examined in vitro. Chicken embryos or cultured kidney cells were inoculated with sporozoites in order to assess viability.Sporozoites of E. tenella survived in phosphate buffer (P.B.S.) containing 0·9 per cent NaCl for 14 days. Some sporozoites survived in solutions containing up to 16 per cent NaCl for 3 days at +4°C. Sporozoites of E. maxima and E. acervulina survived for only 27 h in phosphate buffer containing 1 or 2 per cent NaCl.Sporozoites of E. brunetti, E. maxima, and E. acervulina var: mivati were released rapidly from sporocysts in vitro, but survived for relatively short periods in PBS at 4°C. However, the addition of serum or gelatine to these solutions increased survival to at least 96 h.The viability of sporozoites after freezing and storing in liquid nitrogen was best when 12 per cent dimethyl sulphoxide (DMSO) was added to the sporozoite suspensions. P.B.S. with DMSO was less suitable than the other solutions used and serum or gelatine with the DMSO, was needed to increase survival. Increasing the density of sporozoites in the frozen stabilates did not increase survival.     

Regulation of macrophage populations. I. Preferential induction of Ia-rich peritoneal exudates by immunologic stimuli

The amounts of Ia-positive and -negative macrophages were studied in peritoneal exudates of normal mice or of mice injected with various inflammatory materials, infected with Listeria monocytogenes, or injected with hemocyanin. Ia-negative macrophages predominated in exudates from normal mice or from mice given mineral oil, peptone, thioglycollate, culture media, or endotoxin. Infection with Listeria caused a very marked increase in Ia-positive macrophages. The induction of Ia-positive macrophages by Listeria inoculation resulted in great part from an immune process. The Ia-positive exudates were more readily generated in immune mice given a secondary challenge with heat-killed organisms. Furthermore, immune T cells transplanted together with heat-killed organisms into normal mice resulted in Ia-rich exudates. Injection of hemocyanin also induced Ia-rich exudates involving an immune process. We conclude that an immune reaction involving T cells regulates the Ia phenotype of the exudate macrophage population. The Ia-positive macrophages were Fc and C3 receptor positive and phagocytized latex particles.     

Cryopreservation of Leucocytozoon caulleryi sporozoites

Leucocytozoon caulleryi sporozoites that had been stored at -196 degrees C or -80 degrees C for 6 or 12 months in Eagle's minimum essential medium or Medium 199 supplemented with 5% glycerol and 10% chicken serum showed infectivity to chickens. Glycerol at a concentration of 10% and dimethyl sulfoxide at 10% and 5% were found to be ineffective cryoprotective agents for the low temperature preservation of sporozoites. Sporozoites isolated from the intact females of Culicoides arakawae, which had been stored at -80 degrees C for 6 or 12 months without cryoprotective agents, retained their infectivity. No differences were observed in the prepatent period, duration of parasitemia, and presence of serum-soluble antigens between chickens infected with frozen sporozoites and those infected with fresh sporozoites.     

In Vitro Development of Exoerythrocytic Forms of Plasmodium Gallinaceum Sporozoites In Avian Macrophages

ABSTRACT Exoerythrocytic forms of Plasmodium gallinaceum were cultured in vitro using salivary gland sporozoites extracted from experimentally infected Aedes fluviatilis mosquitoes. the host cells were macrophage precursors from chicken bone marrow. At various times after introduction of Sporozoites, the cultures were stained by Giemsa or by immunofluorescence assay (IFA) using anti-sporozoite-specific monoclonal antibodies (MAb). the time to complete parasite development in vitro was 50-70 h. By 70 h, ruptured segmenters and free merozoites were visible within the cells. Inoculation of normal chickens with infected cultures induced parasitemia after a pre-patent period of 10-11 days. In vitro young exoerythrocytic forms, late schizonts that include the matured segmenters, and free merozoites shared common antigens with the sporozoites as revealed by IFA using anti-sporozoite-specific MAbs. Our data indicate that macrophages support development of P. gallinaceum sporozoites and that the circumsporozoite proteins are present until Ac end of the primary exoerythrocytic schizogony.     

Infectivity of Leucocytozoon caulleryi sporozoites developed in vitro and in vivo

Morii T., Matsui T., Iijima T. and Fiotnaoa F. 1984. Infectivity of Leucocytozoon caulleryi sporozoites developed in vitro and in vivo. International Journal for Parasitology14: 135–139. Infectivity of Leucocytozoon caulleryi sporozoites isolated from various sites in Culicoides arakawae and from the midguts and the salivary glands which had been cultured in vitro after the infective blood meals was studied. Sporozoites isolated from the midguts, the abdominal and thoracic hemocoel and the salivary glands of biting midges on the 2nd day after feeding did not show infectivity to any of the chickens inoculated. Sporozoites obtained from the salivary glands on the 3rd day after feeding caused infection in all the inoculated chickens. The results indicated that sporozoites which had been just released from oocysts or had just reached the salivary glands cannot induce infection in chickens. Sporozoites were produced in the midguts which had been cultured in vitro in Medium 199 or Grace's medium after the infective blood meals, but they showed lower infectivity than those isolated from the salivary glands which had been cultured by the same methods as the midgut cultivation. The development of infectivity of L. caulleryi sporozoites seems to be site-dependent rather than time-dependent. High infectivity of sporozoites develops during their residence in the salivary glands of biting midges.     

Anticoccidial drugs: Effects on infectivity and survival intracellularly of Eimeria tenella sporozoites

The effects of various anticoccidial drugs on extracellular and intracellular sporozoites were studied in cell culture and in chickens. Treatment of freshly excysted, extracellular sporozoites of Eimeria tenella for 18 hr with monensin, decoquinate, or robenidine at 100 ppm had no effect on oocyst production 7–10 days after the sporozoites were rinsed free of drugs and fed to chickens. Treatment of cultures of E. tenella in chick kidney cell monolayers with monensin (0.001 μg/ml), decoquinate (0.01 μg/ml), zoalene (20.0 μg/ml), or robenidine (0.01 μg/ml) had no effect on intracellular sporozoites at 4 hr following introduction of sporozoites and drugs into the culture. A significant reduction of intracellular parasites occurred at 24 hr in the cultures treated with monensin or zoalene. Remaining intracellular sporozoites in monensin-treated cultures were morphologically abnormal or degenerate, while sporozoites in other cultures appeared normal. The number and condition of sporozoites in the nontreated cultures were unchanged at 24 hr postinoculation. These results indicate that sporozoites undergo changes subsequent to penetration of host cells that render them susceptible to drug action.     

Sporozoites of Eimeria acervulina within intestinal macrophages in normal experimental infections: an ultrastructural study.

Sporozoites of Eimeria acervulina were observed in macrophages of the intestinal epithelium 5 and 6 days post-infection. These sporozoites lay within a well developed parasitophorous vacuole, were normal in structure and showed no signs of development. Macrophages harbouring sporozoites showed considerable structural changes, most pronounced being an absence of lysosomes, an enlarged nucleolus and extensive proliferation of the Golgi complex and endoplasmic reticulum. Possible mechanisms of survival and transport of sporozoites to preferred sites of development are discussed.     

Control of normal differentiation of myeloid leukemic cells. IV. Induction of differentiation by serum from endotoxin treated mice

Sera from different strains of mice injected with endotoxin induced clones (D⁺) from a cultured line of myeloid leukemic cells to undergo normal differentiation to mature granulocytes and macrophages. Other clones (D^?) derived from the same cell line were not inducible by these sera to undergo normal cell differentiation. Sera from the same strains of mice that had not been injected with endotoxin, increased the cloning efficiency of D⁺ and D ^? clones but did not induce differentiation. Endotoxin serum induced differentiation in D⁺ cells at dilutions up to 1:64, but increased the cloning efficiency of these cells at dilutions up to 1:2048. The end point of the dilution of endotoxin serum that induced differentiation in D⁺ cells, was also the end point that induced the formation of colonies with differentiation from normal bone marrow cells. The results indicate that serum from endotoxin treated animals can serve as a good in vivo source to induce normal differentiation in D⁺ myeloid leukemic cells; that the progeny of a single leukemic cell was induced to undergo differentiation to both macrophages and granulocytes; that endotoxin serum contained two activities, one that increased cloning efficiency and the other that induced cell differentiation; and that the same material in endotoxin serum induced cell differentiation in normal and leukemic cells.     

Experimental Vaccination of Chicks with Plasmodium gallinaceum Sporozoites. I. Circumsporozoite Proteins Are Expressed by Sporozoites Recovered from Both Salivary Glands and Midguts of Mosquitoes1

Immunogenicity of Plasmodium gallinaceum Sporozoites for chicks and their in vitro reactivity with normal and specific immune sera were studied. Two sporozoite populations recovered from experimentally infected Aedes fluviatilis were used: sporozoites from salivary glands and sporozoites from midgut oocysts. Populations seven to nine days old of sporozoites recovered from salivary glands were infective for all chicks until the chicks were three weeks old; however, sporozoites recovered from midguts containing oocysts infected these chicks only if isolated on days 8–9, but not on day 7 after the mosquitoes' infective blood meal. Infectivity of the sporozoites was lost after exposure to ultraviolet (UV) light (30 min) or X-rays (13 krad). Inactivated sporozoites from both sources proved highly immunogenic to chicks that were immunized by several intravenous or intramuscular injections. These parasites elicited a strong humoral immune response in the chicks, as measured by the circumsporozoite precipitation (CSP) reaction. The levels of the CSP antibodies were similar with sporozoites from both sources, there being no detectable differences in the percentage of reactive sporozoites or the intensity of the CSP reaction with sera containing antibodies to either sporozoites from salivary glands or sporozoites from oocysts. These results provide the first evidence that avian malaria sporozoites express the circumsporozoite protein that has been extensively characterized in mammalian malaria (rodent, simian, human sporozoites). Furthermore, we observed that the yields of sporozoites obtained from mosquito midguts, on days 8 and 9 of the P. gallinaceum infection, were at least twice as great as those obtained by salivary gland dissection, even 20 days after a blood meal. This is an advantage since obtaining the midguts is less tedious, as well as more efficient and faster.     

Interactions of Plasmodium berghei sporozoites and murine Kupffer cells in vitro

Malaria sporozoites must leave the bloodstream and cross a layer of sinusoidal lining cells in order to infect hepatocytes and undergo exoerythrocytic schizogony. To determine whether Kupffer cells (KC) derived from this layer interact with sporozoites, murine KC were isolated from perfused livers of BALB/cJ mice and incubated in vitro with Plasmodium berghei sporozoites. Isolated KC had characteristic macrophage surface Ag and were phagocytic, ingesting both latex particles and Leishmania major amastigotes. In the absence of immune serum, sporozoites associated with fewer than 10% of these KC. By 30 min, 10% of the cell-associated sporozoites were completely ingested, 30% were in the process of being ingested, and 60% were attached to the surface of the cells. Opsonization of sporozoites with monoclonal or polyclonal antibodies directed against P. berghei circumsporozoite protein markedly enhanced sporozoite association with KC. Up to 40% of cells exposed to opsonized sporozoites had parasites inside or attached to their surfaces. Sporozoites attached to or ingested by KC were uniformly destroyed within 240 min in all cultures; there was no evidence of conversion of sporozoites to the exoerythrocytic stage within KC by light microscopy, and there was no evidence of residual sporozoites, either inside or outside of cells, by either light or electron microscopy. These data suggest that under nonimmune conditions, KC play a minor role in resistance to infection by malaria sporozoites. However, when sporozoites are opsonized by circumsporozoite antibodies, phagocytosis by KC may be an important immune mechanism that prevents parasitization of hepatocytes.     

Eimeria tenella: effects of immunity on sporozoites within the lumen of the small intestine

The effect of immunity on the numbers of sporozoites of Eimeria tenella recoverable from the lumen of the small intestine 1 hr after an oral challenge inoculum of oocysts was examined. The experiments were carried out in chickens which had been given an immunizing inoculum of oocysts 9 or 18 days earlier, and the results were compared with those obtained in a control, unprimed, but similarly challenged, group. Similar numbers of "challenge" sporozoites were found in the intestinal washes of control and 18 day primed chickens but there were fewer in the 9 day primed groups. The titers of antisporozoite IgA antibodies (measured by indirect fluorescence) were higher in the gall bladder bile of the 9 day primed groups but resistance to reinfection (measured by the output of oocysts in the feces after challenge with oocysts orally or with sporozoites intracecally) was greater in the 18 day primed group. Although fewer in number, the challenge sporozoites recovered from the intestinal washes of 9 day primed chickens appeared to be morphologically normal when examined by light microscopy. Also, they were as infective as sporozoites recovered from unprimed control, or 18 day primed, groups when injected intracecally into naive chickens. The findings indicate that, whereas reduction of the number of sporozoites of E. tenella in the lumen of the small intestine (presumably caused by the action of secreted antibodies) can be a means of reducing the effective challenge inoculum, this mechanism does not play a major role in the expression of immunity.     

The Migration of Eimeria acervulina Sporozoites to the Duodenal Glands of Lieberkühn

SYNOPSIS. The establishment of Eimeria acervulina sporozoites in the duodenal glands of Lieberkühn of the chicken is described. Sporozoites were found to enter the tips of the villi and pass into the lamina propria, or core, of the villus. Within the lamina propria, sporozoites were engulfed by macrophages and taken to the glandular epithelium.
Data are presented which indicate that macrophages serve as a defense against infection as well as a mode of transportation.